Yes, what fuel is used by the plants will depend on location. On the East Coast, I believe coal still largely rules, given the closeness of supply. Hydroelectric will also be a factor, if there are places nearby that *can* be dammed to produce power. (Most locations that can be, *are*, so there isn't a lot of growth from hydro power possible.) Nuclear has a tiny slice of the pie that is likely to rise as demand does. Oil essentially isn't used - I heard of one generating plant that had oil as a backup for natural gas, but dropped it when gas supplies proved stable enough it would never be used.
But basically, the fuel used to boil the water to generate steam to spin the generators that make the electricity isn't really a huge factor in electricity costs. I was involved in a government sponsored project to push alternative energy back in the 70's when OPEC was in first flower and gas prices were rising above $1/gallon. The issue wasn't electric power costs, it was heating and cooling, as many places used oil to fire the boilers that produced heat. We pushed solar hot water heating, which accounted for about 20% of the average residential energy bill, and had a relatively fast payoff. We were certainly *aware* of other forms of alternative energy, like photovoltaics, but what would get used would ultimately be what was cheapest, and most alternatives were just too expensive with too long a payback period.
For the most part, oil still *is* cheaper overall, which is why alternatives have an uphill fight. People forget that electricity is only one form of energy used, and is about 25% of the total US energy budget.
Thinking that a few years is "persistence" is what is dooming us in the long run. What happens when the fracking boomlet dries up? We will have burned our bridge fuel in a gluttonous rush rather than milking it slowly as we transisition to something that can last.
"I believe the majority of plants are still coal fired."
On the US West coast, over 50% of electricity comes from natural gas. Coal is negligible--the few plants left are being phased out.
Wind supplies 5% of California's electric power. More than twice as much as generated by coal.
I think putting solar panels on roofs makes a lot of sense--it puts the power right where it is used. Most government solar energy numbers don't even count the rooftop panels and end up underestimating the amount of solar power generated by a very large percentage.
I did assume that operators like Bonneville Power had a better handle on how to integrate hydro and wind into the NW grid. Sounds like most of these outfits are unwilling to take a risk in order to upgrade the grid.
The pitiful state of the grid is going to be the largest barrier, beyond tariffs or even batteries. Renewables tend to be available only in specific places, rarely where demand is.
Here in Washington State you would think our plentiful wind and water should play well together, since water is an ideal storage system with rapid demand scaling. However, we have times of high wind where we idle the mills and use hydro, because our grid works for hydro but is not able to deliver wind power to where it is needed.
The building of grids however is capital intensive and a long term return. Which is not a good match to new technology like wind or solar which is rapidly changing. Perhaps in a few places the investments in grids make sense because they pay off under multiple scenarios, but those which involve long spurs (like the Pacific coast for wind) for single purpose are going to make any investor nervous.
Solar is another example of "second-generation innovation" by China in which huge amounts of resources were poured into what central planners believed was a profitable market. Too many Chinese solar panel makers got too much money from Beijing, and now, as you point out, they are paying the price.
The solar power industry’s problem is not China, it’s economics. It costs too much. It’s not competitive. Its survival depends on government subsidies. Governments are beginning to recognize that solar is not nor will be competitive and are gradually reducing subsidies. The solar power industry assumed the cost of electricity would increase with the addition of carbon pricing coupled with tight fossil fuel supply. In other words, environmental costs and fuel costs would increase the cost of electric power to the point where solar would be competitive. The problem with this reasoning is that it ignores the benchmark for clean electric power, nuclear. Safety concerns notwithstanding, nuclear power sets the bedrock price for clean electric power. Even if the cost for the solar cells were zero dollars/watt, solar compared to nuclear is too expensive.
I think you mean $500 *million*, which is what Solyndra got from the US government, and is not even visible on the government's bottom line.
You can argue the government screwed up by extending the loan at all, but the amount is relative chicken feed.
What are the engineering and design challenges in creating successful IoT devices? These devices are usually small, resource-constrained electronics designed to sense, collect, send, and/or interpret data. Some of the devices need to be smart enough to act upon data in real time, 24/7. Are the design challenges the same as with embedded systems, but with a little developer- and IT-skills added in? What do engineers need to know? Rick Merritt talks with two experts about the tools and best options for designing IoT devices in 2016. Specifically the guests will discuss sensors, security, and lessons from IoT deployments.